A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

An exemplary method for controlling a vehicle includes receiving, by a vehicle controller, sensor data representing a first operating condition of the vehicle from at least one sensor, determining, by the vehicle controller, a temperature of a vehicle braking system of the vehicle, determining, by the vehicle controller, if the temperature of the vehicle braking system exceeds a temperature threshold, and if the temperature of the vehicle braking system exceeds the temperature threshold, generating, by the vehicle controller, a control signal to move a moveable underbody feature from a first position to a second position.

A motorized vehicle includes an engine, a transmission having an input coupled to the engine and an output, and a controller for controlling at least the transmission. A braking system includes a brake sensor and a brake pack configured to reduce a speed of the vehicle. The brake sensor is disposed in electrical communication with the controller. A main hydraulic pump is operably driven by the engine and an output hydraulic pump is operably driven by the transmission output. A brake coolant valve is disposed in fluid communication with the main hydraulic pump and the output hydraulic pump. The brake coolant valve is controlled between an open position and a closed position. The main hydraulic pump and the output hydraulic pump are fluidly coupled to the brake pack when the brake coolant valve is in its open position.

The flywheel device includes a sealed housing section; a rotor located in the sealed housing section where the rotor is held in a vertical position by a magnetic system; a controller coupled to the magnetic system; and a braking annular ring mounted to the sealed housing section below the rotor, where the rotor contacts the braking annular ring when the rotor is lowered or otherwise dropped from the vertical position. The controller performs operations to provide control signals to provide first power to the magnetic system to hold the rotor in the vertical position and provide second control signals to provide second power to the magnetic system to lower the rotor.

A method of cooling an aircraft brake including a brake pack and a reservoir in the form of a removable cartridge containing a coolant. The method includes vaporizing the coolant using heat energy from the brake pack.

A disc brake and a cooling controller, a control system and a control method, a brake disc of the disc brake includes a first basic plate and a second basic plate, jointed and forming a cavity. A fibrous body having a capillary structure is sandwiched between the first basic plate and the second basic plate, the fibrous body filling between the first basic plate and the second plate, and the fibrous body being formed in a ring shape and sleeves on an axle to receive cooling water from the axle and distribute the cooling water on inner walls of the first basic plate and the second basic plate. The cooling water is evenly distributed to prevent brake disc from fading under heat, and based on the disc brake, an additional automatic controlled cooling control system is provided to accurately control the amount of the cooling water, thereby saving water.

An aerodynamic system for a wheel housing of a vehicle that according to one embodiment includes a flap that can be displaced between a deployed position and a retracted position, a rotating actuator, and a transmission mechanism coupled to the actuator and configured for transmitting the movement of the actuator to the flap. The aerodynamic system also includes at least one air flow shutter device in the wheel housing, where the shutter device faces at least one air duct and where the shutter device can be displaced between a closed position and an open position. The transmission mechanism is also configured for transmitting the movement of the actuator to the shutter device.

The present invention relates to a method for controlling a vehicle in association with a descent, the vehicle having a powertrain comprising: a drive unit configured to provide propulsion power; an auxiliary brake device; and a first cooling circuit comprising a first coolant; wherein the drive unit and the auxiliary brake device are arranged to be selectively connected or disconnected with/from the first cooling circuit, wherein the drive unit has a first maximum temperature and the auxiliary brake device has a second maximum temperature higher than the first maximum temperature, the method comprising: controlling the drive unit to reduce the provided propulsion power when the vehicle is approaching an upcoming descent, which fulfils predetermined criteria; disconnecting the drive unit from the first cooling circuit; connecting the auxiliary brake device with the first cooling circuit; and controlling the auxiliary brake device to brake to vehicle down the descent.

A motor vehicle with a first and a second wheel; a control member, which can be activated; a first and a second braking device, which can be operated by means of the control member; and a braking control system, which is connected to the control member and is provided with a first fluidic line and with a second fluidic line connected to the control member and to a first a first and a second chamber of the first braking device; a third fluidic line fluidically connected to one of the first and the second chamber; and a control valve, which can be moved between a first position, in which it connects the third fluidic line to the second fluidic line and isolates the second fluidic line from the second chamber; and a second position, in which it isolates the third fluidic line from the second fluidic line and connects the second fluidic line to the second chamber; and a control unit programmed to acquire an operating state of the control member and a plurality of operating parameters of the motor vehicle and to move the control valve from the second position to the first position for a limited amount of time.